Quantification of strong emissions of methane in the

Arctic using spectral measurements from TANSO-FTS

and IASI

Zakia Bourakkadi, Sebastien Payan, Jerome Bureau

To cite this version:

Zakia Bourakkadi, Sebastien Payan, Jerome Bureau. Quantification of strong emissions ofmethane in the Arctic using spectral measurements from TANSO-FTS and IASI. EuropeanGeosciences Union General Assembly 2015, Apr 2015, Vienne, Austria. pp.EGU2015-3243.<hal-01142226>

HAL Id: hal-01142226

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Submitted on 20 Apr 2015

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B) IASI

Quantification of strong emissions of methane in the Arctic using spectral measurements from TANSO-FTS and IASI

Z . BOURAKKADI1 , S. PAYAN1, J. BUREAU1

1- Université Versailles St-Quentin, Sorbonne Universités, UPMC Univ. Paris 06; CNRS/INSU, Latmos-IPSL, 4 Place Jussieu 75252

Paris Cedex 05 France

Contact : zakia.bourakkadi@latmos.ipsl.fr

Introduction Methane is the second most important greenhouse gas in the atmosphere after carbon dioxide, but it is 25 times more effective in terms of radiative forcing (IPCC-2007). It plays also an important role in atmospheric ozone chemistry.

Since the pre-industrial times global methane concentrations have more than doubled in the atmosphere, and this increase is generally caused by anthropogenic activities like the massive use and extraction of fossil fuel, rice paddy agriculture and emissions from landfills.

In the Arctic region, methane emissions from thawing permafrost become potentially important due to climate warming and the large carbon pools stored in this region. These emissions are controlled by the temperature, and because methane is a greenhouse gas its

emission could entail positive feedback, so it is very important to monitor and quantify its concentration in the atmosphere in real-time. This study consists of evaluating and quantifying methane strong emissions in the Arctic region using measurements in the TIR from

IASI and TANSO-FTS.

I. Instruments

II. Sensibility of TANSO-FTS and IASI to detect hotspots of CH4 on the surface To study the sensibility of TANSO-FTS and IASI to detect high methane surface emissions, we used simulations from MACC-II (Monitoring Atmospheric Composition and Climate-II) . MACC-II is a high-resolution model (0.125°x0.125°, 137 pressure levels and 3 hours of temporal resolution), it’s based on

TM5-4DVAR inverse modeling system (Bergamashi et al., 2010). MACC-II used satellite retrievals from SCIAMACHY until end of 2011, but since the beginning of 2012 the GOSAT RemoteC PROXY v2.0 XCH4 retrievals have been used. We choose period of high surface methane emission in Canada during 2013 according to the biomass burning emission inventory used by the model.

Maximum of methane between 5 and 10 km was observed on July 6th at

midnight.

We extracted set of methane profiles, which correspond to high values of

methane between 5 and 10 km to simulate their spectra.

To compute this set of spectra, we used LARA algorithm (LATMOS

Atmospheric Retrieval Algorithm).

The temperature profiles, pressure profiles and humidity profiles are

extracted from ECMWF model.

We used the instrumental function of IASI and that of TANSO-FTS to

compute spectra for each instrument.

IASI is capable to detect high values of methane due to a strong methane emissions on the surface.

Conclusion and outlook The results presented in this study show that TANSO-FTS and IASI allow to identify peaks of methane surface emissions with

short duration transported to the layer between 5 and 10 km. We will add noise to our simulated spectra in order to study the ability of LARA algorithm to retrieve profile of methane and then

model to inverse initial emission. In collaboration with LSCE laboratory, we will use the LMDZ-PYVAR to quantify methane emissions in the Arctic region.

As TANSO-FTS, we compute the differences in brightness temperatures between each IASI spectrum simulated with

high values of methane and that with current values of methane, and then we compare the differences in BT to IASI

noise equivalent delta temperature.

The spectral points which correspond to a difference in BT

less than IASI noise do not overlap with methane spectrum.

Acknowledgements We acknowledge our colleagues at LSCE laboratory for their MACC-II data contribution.

References Bergamaschi, P., M. Krol, J. F. Meirink.: Inverse Modeling of European CH4 Emissions 2001–2006, Journal of Geophysical Research: Atmospheres 115(D22): D22309, 2010. C. Clerbaux, A. Boynard, L. Clarisse, M. George, J. Hadji-Lazaro, H. Herbin, D. Hurtmans, M. Pommier,A. Razavi, S. Turquety, C. Wespes, and P.-F. Coheur.: Monitoring of atmospheric composition using the thermal infrared IASI/MetOp sounder, Atmospheric Chemistry and Physics, August 2009. IPCC-2007 (Intergovernmental Panel on Climate Change (2007)), Climate Change 2007: The Physical Sience Basis, edited by S. Solomon et al., Combrige Univ.Press, Cambrige, U.K.

http://www.gosat.nies.go.jp/eng/gosat/page3.htm

IASI

noise 0.1K

Pic of methane by

biomass burning

emission observed

on July 2013 over

Canada

We analyzed data from MACC-II for a 8 days period (from July 1st to 8th ) which correspond to the maximum of surface

methane emission in the set of data.

Strong methane surface emissions

are seen on July 3rd and 4th.

On July 3rd , the emission lasted 12

hours (from 3:00 to 15:00 UTC).

On July 4th, it lasted 9 hours (from

3:00 to 12:00 UTC).

Because the sensibility of IASI and

TANSO-FTS to methane is higher

between 5 and 10 km (and not

close to the surface), we selected

data with high column of methane

between these two layers. Then,

using the extracted methane

profiles, we compute a set of

spectra.

2) IASI /MetOp IASI (Infrared Atmospheric Sounding Interferometer ) is a Fourier transform spectrometer at nadir looking based on a Michelson interferometer coupled to an imaging instrument, designed to measure the spectrum emitted by the earth-atmosphere system in the thermal infrared radiation (TIR).

Spectral resolution : 0.5 cm-1

Spectral coverage : 645 cm-1 – 2760 cm-1

Noise equivalent at 280 K in the spectral range of interest for methane : 0.1K

IASI provides global Earth’s coverage twice a day.

1) TANSO-FTS /GOSAT

TANSO-FTS (Thermal And Near Infrared Sensor for Carbon Observations) is a nadir looking Fourier Transform Spectrometer

that observes sunlight reflected from the earth’s surface and the light emitted from the atmosphere and surface.

Spectral resolution : 0.2 cm-1

Spectral coverage : 3 bands in the SWIR centered at 13158, 6250 and and 5000 cm-1 and one band in the TIR (700 – 1800 cm-1).

TANSO-FTS takes 56 000 measurements covering the globe in 3 days.

C. Clerbaux et al., 2009

To study the capacity of TANSO-FTS and IASI to detect high

values of methane due to strong emissions on the surface, we

compare the differences in brightness temperature between

spectra with high values of methane and that with current

values to the thermal noise of TANSO-FTS and IASI.

C. Clerbaux et al., 2009

A) TANSO-FTS

The spectral points corresponding to a difference in

BT < than TANSO-FTS noise does not overlap with

methane lines.

TANSO-FTS

Noise 0.2K

We computed for each TANSO-FTS simulated spectrum the differences between its brightness temperatures and the

brightness temperatures of the spectrum with current values of methane (spectrum of reference).

We compared the differences in brightness temperature to TANSO-FTS noise equivalent delta temperature.

TANSO-FTS is capable to detect a high values of methane due to a strong methane emissions on the surface.

1) Results :

http://www.gosat.nies.go.jp/eng/gosat/page3.htm